KR102210153B1 - Double heat exchanger and sewage sludge dryer using the same - Google Patents

Abstract

According to an embodiment of the present invention, as a heat exchanger of a sewage sludge drying system, an exhaust gas inlet and an outlet are formed, and an internal space through which the exhaust gas moves is formed; A heat medium oil heating unit located in the inner space and transferring heat of the exhaust gas to a heating medium oil moving therein to heat the heat medium oil; And a carrier air heating unit located in the inner space and transferring heat of the exhaust gas to the carrier air moving therein to heat the carrier air, wherein the heated heat medium oil is connected to the heat medium oil heating unit. It provides a double heat exchanger, characterized in that it moves to the dryer of the sewage sludge drying system along the oil outflow path, and the heated carrier air moves to the dryer along the air outflow path connected to the carrier air heating part. .
In addition, according to another embodiment of the present invention, as a dryer of a sewage sludge drying system, a case in which a sewage sludge inlet and an outlet are formed, and a first inner space through which the sewage sludge moves; It is disposed rotatably in the first inner space, and transfers heat of heating medium oil that moves through the second inner space formed therein to the sewage sludge introduced into the inlet to dry the sewage sludge, and the drying Moving means for moving the sewage sludge in the direction of the discharge port; A carrier air inlet formed outside the case and through which carrier air is introduced from the heat exchanger of the sewage sludge drying system; And a carrier air outlet portion formed on the outside of the case and through which floating matter generated by drying of the sewage sludge flows out with the carrier air, and the heat medium oil comprises an oil outlet path connected to the second inner space. It provides a sewage sludge dryer, characterized in that moved from the heat exchanger.

Description

Double heat exchanger and sewage sludge dryer using the same {DOUBLE HEAT EXCHANGER AND SEWAGE SLUDGE DRYER USING THE SAME}

The present invention relates to a sewage sludge drying system, and more specifically, a dual heat exchanger that dries sewage sludge using a thermal medium oil and heated air, and improves energy efficiency of a drying system by adopting a structure optimized for sludge pulverization. And it relates to a sewage sludge dryer using the same.

The content described in this section merely provides background information on the present invention and does not constitute prior art.

Sewage sludge refers to a sediment generated during sewage treatment or water purification. In the past, studies on the utilization of sewage sludge have not been actively conducted, and thus sewage sludge has been treated by dumping sewage sludge into the ocean or by burying it underground.

However, these methods not only pollute the ocean or soil to cause environmental pollution, but also cause problems such as a lack of space for landfilling the sewage sludge that is continuously generated.

Recently, in order to solve such a problem, a method of removing moisture contained in sewage sludge through a drying process and utilizing the dried sewage sludge as an auxiliary fuel for thermal power generation has been attempted.

The method of drying the sewage sludge can be largely divided into a direct drying method in which the sewage sludge is dried by exposing it to dried high heat air and an indirect drying method in which the sewage sludge is dried indirectly using high heat steam.

However, in the case of the direct drying method, high-heat dry air is generated using fuel having a relatively high calorific value, and dried sewage sludge having a relatively low calorific value (about 3000 kcal/kg) is generated using this It can be said to be inefficient.

In addition, in the case of the indirect drying method, steam is generated by utilizing high-temperature exhaust gas generated from a power plant or an incinerator. Considering that more heat is required to change the phase of water from liquid to gas (steam), This method is also not an efficient method.

Accordingly, there is a need for a new method of improving energy efficiency for a process of drying sewage sludge.

An embodiment of the present invention is to dry the sewage sludge using a thermal medium oil that does not need a phase change and heated external air, and pulverize the sewage sludge in the drying process to increase the thermal contact area with the thermal medium oil. The main object is to provide a dual heat exchanger that improves energy efficiency for sludge drying and a sewage sludge dryer using the same.

According to an embodiment of the present invention, as a heat exchanger of a sewage sludge drying system, an exhaust gas inlet and an outlet are formed, and an internal space through which the exhaust gas moves is formed; A heat medium oil heating unit located in the inner space and transferring heat of the exhaust gas to a heating medium oil moving therein to heat the heat medium oil; And a carrier air heating unit located in the inner space and transferring heat of the exhaust gas to the carrier air moving therein to heat the carrier air, wherein the heated heat medium oil is connected to the heat medium oil heating unit. It provides a double heat exchanger, characterized in that it moves to the dryer of the sewage sludge drying system along the oil outflow path, and the heated carrier air moves to the dryer along the air outflow path connected to the carrier air heating part. .

According to another embodiment of the present invention, as a dryer of a sewage sludge drying system, a case in which a sewage sludge inlet and an outlet are formed, and a first inner space through which the sewage sludge moves; It is disposed rotatably in the first inner space, and transfers heat of heating medium oil that moves through the second inner space formed therein to the sewage sludge introduced into the inlet to dry the sewage sludge, and the drying Moving means for moving the sewage sludge in the direction of the discharge port; A carrier air inlet formed outside the case and through which carrier air is introduced from a heat exchanger of the sewage sludge drying system; And a carrier air outlet portion formed on the outside of the case and through which floating matter generated by drying of the sewage sludge flows out with the carrier air, and the heat medium oil comprises an oil outlet path connected to the second inner space. It provides a sewage sludge dryer, characterized in that moved from the heat exchanger.

In the present invention, since the heat medium oil and the external air are heated using a single heat source, exhaust gas, and the heated heat medium oil and the heated external air are used double or mixed to dry the sewage sludge, Can improve energy efficiency.

In addition, the present invention pulverizes the sewage sludge using a structure optimized for pulverizing sewage sludge, so that the contact area between the heated thermal medium oil or heated external air and the sewage sludge increases, thereby improving energy efficiency for sewage sludge drying. It can be further maximized.

Further, the present invention is configured to prevent the condensation of sewage sludge dust from which heated external air flows to the outside, so that suspended matter generated during the drying of sewage sludge can be more effectively removed, and thus a drying process can be implemented smoothly.

1 is a view for explaining an embodiment of a sewage sludge drying system comprising a double heat exchanger and a dryer of the present invention.
2 is a view for explaining an embodiment of the heat exchanger according to the present invention.
3 is a view for explaining an embodiment of the dryer according to the present invention.
4 is a view for explaining an embodiment of the present invention for a structure for pulverizing sewage sludge.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to elements of each drawing, it should be noted that the same elements are assigned the same numerals as possible even if they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

In addition, in describing the constituent elements of the present invention, terms such as first, second, A, B, (a), (b) may be used. These terms are only used to distinguish the component from other components, and the nature, order, or order of the component is not limited by the term. Throughout the specification, when a part'includes' or'includes' a certain element, it means that other elements may be further included rather than excluding other elements unless otherwise stated. .

1 is a sewage sludge drying system comprising a double heat exchanger (hereinafter referred to as a'heat exchanger') 100 and a sewage sludge dryer (hereinafter referred to as a'dryer') 200 of the present invention (hereinafter It is a diagram for explaining an embodiment of the'drying system') (1000). Hereinafter, a drying system 1000 of the present invention will be described in detail with reference to FIG. 1.

As shown in Fig. 1, the drying system 1000 according to the present invention may include a heat exchanger 100, a dryer 200, and a collector (Cyclone, 300). First, the heat exchanger 100 of the present invention corresponds to a device that heats a heating medium oil and a carrier gas to provide the dryer 200 of the present invention.

Since the external air heated in the heat exchanger 100 can be used for removing water vapor and sludge dust generated during sewage sludge drying, as described later, the external air will be referred to as carrier air hereinafter.

The exhaust gas flowing into the heat exchanger 100 is exhaust gas generated from a power plant or an incinerator, and has its own temperature sufficient to heat the thermal medium oil and carrier air to a specific temperature.

Here, the specific temperature of the thermal medium oil means the temperature above the minimum temperature that can be used for drying the sewage sludge, and the specific temperature of the carrier air means the temperature above the minimum temperature that can be used for drying the sewage sludge, or the condensation of the sewage sludge dust. It means the temperature above the minimum temperature that can prevent the phenomenon.

The thermal medium oil and carrier air heated by the exhaust gas flow into the dryer 200 of the present invention through a moving path connecting the heat exchanger 100 and the dryer 200, and the exhaust gas is the thermal medium oil and the carrier air. It is used to heat air and then flows out to the outside.

As shown in FIG. 1, the dryer 200 of the present invention uses the (heated) thermal medium oil and (heated) carrier air introduced from the heat exchanger 100 to dry the sewage sludge introduced from the outside. It corresponds to the device.

Sewage sludge introduced into the dryer 200 contains a certain amount (or a certain percentage) or more of moisture (water content), and is dried to contain less than a certain amount of moisture through a drying process using thermal medium oil and carrier air. Is produced and discharged to the outside.

Here, the moisture content of the sewage sludge to be achieved through the drying process may mean the moisture content that the sewage sludge can be used as an auxiliary fuel for a thermal power plant or other purposes without a separate additional process.

Accordingly, the moisture content of the dried sewage sludge may be variably set according to the purpose of the dried sewage sludge such as thermal power generation, the intention of the user, and the like.

The movement of the sewage sludge inside the dryer 200 is implemented by the moving means 220 of the present invention. Specifically, the moving means 220 of the present invention moves the sewage sludge introduced from the outside in the direction of the discharge port by its own rotational motion.

The thermal medium oil, which has been used for drying the sewage sludge and whose temperature has been lowered, is discharged to the outside through a separate outlet. The present invention re-introduces and reheats the heat medium oil recycled to the outside, that is, used for drying sewage sludge, into the heat exchanger 100 of the present invention, and reuses it for drying sewage sludge. Is configured to use cyclically.

The carrier air, which has been used for drying the sewage sludge and whose temperature has been lowered, is discharged in the direction of the collector 300 through a separately formed outlet using the collecting force of the collector 300 corresponding to the dust collection facility. Moisture and sewage sludge dust generated in the process of drying the sewage sludge are discharged in the direction of the collector 300 together with the carrier air (mixed with the carrier air).

2 is a view for explaining an embodiment of the heat exchanger 100 according to the present invention. Hereinafter, with reference to FIG. 2, a description will be given of the technical features of the present invention for providing a thermal medium oil and a carrier air by double heating.

As shown in FIG. 2, the heat exchanger 100 of the present invention includes a case 105, an exhaust gas inlet 111, an exhaust gas outlet 113, a heat medium oil heating unit 130, and a carrier air heating unit 140. ) Can be included.

First, in the case 105 of the present invention, an exhaust gas inlet 111 through which exhaust gas is introduced from the outside is formed on one side (outer side), and an exhaust gas outlet 113 through which exhaust gas is discharged is formed on one side (outside). Is formed in

2 shows the exhaust gas inlet 111 and the exhaust gas outlet 113 formed on different sides, but according to the embodiment, the exhaust gas inlet 111 and the exhaust gas outlet 113 are identical to the case 105 It may be formed on the side, and may be formed on a side different from the side shown in FIG. 2.

Inside the case 105, an internal space 120 through which the exhaust gas introduced from the outside moves is formed, and the internal components of the heat exchanger 100 to be described later may be formed, arranged, or installed in the internal space 120. have.

The heating medium oil heating unit 130 of the present invention is located in the inner space 120 and corresponds to a configuration that heats the heat medium oil by transferring heat of the exhaust gas to the heat medium oil moving therein.

The thermal medium oil heated by the heating medium oil heating unit 130 moves to the dryer 200 of the present invention along the oil outflow path 33 connected to the thermal medium oil heating unit 130 and is used for drying sewage sludge.

The thermal medium oil in the state before being heated, that is, the thermal medium oil flowing into the heating medium oil heating unit 130, corresponds to the thermal medium oil used for drying sewage sludge in the dryer 200 of the present invention, or other than the dryer 200. It may correspond to the thermal medium oil introduced by the cause.

Specifically, the thermal medium oil may correspond to a new thermal medium oil that is introduced into the heating medium oil heating unit 130 by an administrator or a user, and according to the embodiment, the thermal medium oil is used for drying sewage sludge in the dryer 200. It may correspond to the thermal medium oil introduced from the dryer 200 along the oil inflow path connected to the heating unit 130.

In the case of the embodiment in which the thermal medium oil used for drying the sewage sludge is re-introduced into the heating medium oil heating unit 130 among various embodiments of the present invention, the thermal medium oil can be recycled, thus providing the effect of efficient use of resources. can do.

The structure of the heating medium oil heating unit 130 shown in FIG. 2 will only represent any one of various structures that can be implemented in the present invention. The heat medium oil heating unit 130 of the present invention may have various structures according to parameters such as a user's intention, the size of the internal space 120, and a heating temperature to which the heat medium oil must reach.

On the other hand, the carrier air heating unit 140 of the present invention is located in the inner space 120 and corresponds to a configuration that heats the carrier air by transferring heat of exhaust gas to the carrier air moving therein.

Carrier air can be introduced into the carrier air heating unit 140 of the present invention through the air inflow path 41 formed in the case 105, and the heated carrier air is an air outflow path connected to the carrier air heating unit 140 It may be moved to the dryer 200 along 43 and used for drying sewage sludge, or used for discharging suspended matter containing moisture and sewage sludge dust.

The structure of the carrier air heating unit 140 shown in FIG. 2 will only represent any one of various structures that can be implemented in the present invention. The carrier air heating unit 140 of the present invention may have various structures according to parameters such as a user's intention, the size of the inner space 120, and a heating temperature to which the carrier air must reach.

As described above, since the heat exchanger 100 of the present invention is configured to heat both the thermal medium oil and the carrier air and transfer the two heated objects to the dryer 200, the energy for drying the sewage sludge implemented in the dryer 200 The efficiency can be further improved.

In addition, when the heat exchanger 100 of the present invention is configured to reheat the thermal medium oil used for drying sewage sludge, since the reuse rate of the thermal medium oil can be increased, the heat exchanger 100 of the present invention is more efficient in resources. It can provide the effect of using it.

3 is a view for explaining an embodiment of the dryer 200 according to the present invention. Hereinafter, a dryer 200 of the present invention for more efficiently drying sewage sludge by using both the thermal medium oil and the carrier air will be described in detail with reference to FIG. 3.

3, the dryer 200 of the present invention includes a case 205, a sewage sludge inlet 211, a sewage sludge outlet 213, a first inner space 220, a moving means 230, and 2 It may be configured to include an inner space 237, a carrier air inlet 241 and a carrier air outlet 243.

First, the case 205 of the present invention is a configuration that performs the case function of the dryer 200, and the sewage sludge inlet 211 into which the sewage sludge is input (before drying) is formed on one side, and the sewage sludge (after drying) The sewage sludge input port 211 is formed on one side.

Hereinafter, in order to more easily distinguish the case 105 of the heat exchanger 100 from the case 205 of the dryer 200, the case 205 of the dryer 200 will be referred to as a dryer case 205. .

3 shows the sewage sludge inlet 211 and the sewage sludge outlet 213 formed on different sides, but according to the embodiment, the sewage sludge inlet 211 and the sewage sludge outlet 213 may be formed on the same side. In addition, it may be formed on a side different from the side surface shown in FIG. 3.

In the case 205, that is, the dryer case 205, a first internal space 220, which is an internal space in which sewage sludge moves, is formed, and the lower components of the dryer 200 to be described later are formed in the first internal space 220. It can be placed, positioned or installed.

The moving means 230 of the present invention moves the sewage sludge from the sewage sludge input port 211 side to the sewage sludge discharge port 213 through a rotational motion (dashed chain arrow) within the first internal space 220, and It is a configuration in which the heat of the medium oil is transferred to the sewage sludge to dry the sewage sludge.

As shown in Fig. 3, the moving means 230 is provided with a second inner space 237, which is an inner space through which the thermal medium oil moves (solid arrow). In addition, the thermal medium oil moving in the second inner space 237 corresponds to the thermal medium oil that has moved from the heat exchanger 100 along the oil outflow path 33 connected to the second inner space 237.

When the drying system 1000 of the present invention is configured to recycle the thermal medium oil, the thermal medium oil used for drying the sewage sludge in the moving means 230 is the oil inflow path 31 connected to the second inner space 237 It is re-inflowed into the heat exchanger 100 along the line.

The carrier air inlet 241 of the present invention is formed on the outside (one side) of the dryer case 205, and the carrier air heated in the heat exchanger 100 flows from the heat exchanger 100 along the air outflow path 43 It corresponds to the configuration.

The introduced carrier air comes into contact with the sewage sludge, and the high heat of the carrier air is transferred to the sewage sludge to dry the sewage sludge. As described above, the present invention is configured to use the heat of the carrier air as well as the heat of the heat medium oil to dry the sewage sludge, so that more rapid drying can be realized.

In addition, since the heating of the carrier air is not implemented through a separate heat source, but through the same heat source (exhaust gas) as the heating of the thermal medium oil, the present invention can further improve the energy efficiency for drying sewage sludge. .

The carrier air outlet 243 of the present invention is a configuration corresponding to the carrier air inlet 241, is formed on the outside (one side) of the dryer case 205, and is formed on the outside (one side) of the dryer case 205, and the floating matter (water, sewage sludge dust) generated by the drying of the sewage sludge Etc.) corresponds to the configuration that flows out to the collector 300 along the collection pipe 45 together with the carrier air.

When unheated carrier air is used for removal or outflow of suspended matter, as the temperature of the moisture decreases, sewage sludge dust is combined with moisture and condensed, and the condensed sewage sludge lump is transferred to the carrier air outlet (243) and collecting pipe (45). ), may be accumulated in the collector 300.

When the sewage sludge lumps accumulate, the area of the path through which the floating material is discharged becomes narrow, so that the floating material does not flow smoothly, and the drying performance of the dryer 200 may be deteriorated.

The present invention can solve this problem by being configured to discharge the floating material using the carrier air heated in the heat exchanger 100, not the unheated carrier air. That is, since the heated carrier air has a high temperature, the moisture generated by the drying of the sewage sludge maintains a gaseous state, and the present invention prevents condensation or agglomeration of the sewage sludge dust and the accumulation of the sewage sludge mass. I can.

4 is a view for explaining an embodiment of the present invention for a structure for pulverizing sewage sludge. Hereinafter, the structure of the present invention optimized for crushing sewage sludge will be described with reference to FIGS. 3 and 4.

As shown in FIGS. 3 and 4, the moving means 230 of the present invention may include a main frame 231 and a main disk 233. First, the main frame 231 of the present invention is a configuration constituting a main shaft or a rotating shaft of the moving means 230, and rotates, and the heated thermal medium oil moves through the second inner space 237 formed therein.

The main disk 233 of the present invention is a configuration for guiding the movement of sewage sludge and crushing the sewage sludge, and is formed or disposed on the outer surface of the main frame 231 as shown in FIGS. 3 and 4. , One or more is formed or disposed along the movement direction of the sewage sludge.

In addition, the main disk 233 of the present invention may be formed to have a shape protruding from the rotation axis of the main frame 231 in the direction of the first inner space 220 as shown in FIG. 4. Further, the main disk 233 of the present invention may have a structure inclined toward the sewage sludge discharge port 213 in order to induce smooth movement of the sewage sludge.

3 and 4 show the main disk 233 having a square shape, but the main disk 233 of the present invention has a triangular shape according to the degree of pulverization of sewage sludge, smooth movement of sewage sludge, and user's intention. It can be formed in various shapes such as a curved shape.

As described above, when the moving means 230 of the present invention includes the main frame 231 and the main disk 233, more frequent friction or collision occurs between the sewage sludge and the moving means 230, and such friction Alternatively, due to collision, sewage sludge having a relatively large volume at the beginning of input may be pulverized into sewage sludge having a relatively small volume.

When the sewage sludge has a relatively small volume, the contact area and contact frequency between the heat of the carrier air or the heat of the thermal medium oil and the sewage sludge increase, so that more rapid sewage sludge drying can be realized.

According to the embodiment, as shown in Figure 4, the present invention is disposed on the inner surface of the dryer case 205, further includes one or more sub-disks 235 having a shape protruding in the direction of the first inner space 220 It can be configured.

If the present invention is configured to further include the sub-disc 235, the friction or collision with the sewage sludge occurs not only in the moving means 230 but also in the inner upper side of the dryer case 205, so that the sewage sludge is dried quickly. The effect that can be implemented can be further increased.

In a different embodiment, the sub-disc 235 of the present invention may be disposed at a position corresponding to one or more clearance spaces 237 formed between the main discs 233. Specifically, as shown in FIG. 4, the sub-disc 235 of the present invention may be formed at a position where the main discs 233 are fitted. In addition, the sub-disc 235 of the present invention is formed to have a predetermined spacing distance, rather than contacting the main discs 233.

When the present invention is configured in this way, in addition to friction and collision with sewage sludge, the size of the space formed between the fitted sub-disc 235 and main disc 233 (a space created by a preset separation distance) Since the sewage sludge can be pulverized to a size corresponding to that, the sewage sludge can be pulverized to a smaller size.

The above description is merely illustrative of the technical idea of the present embodiment, and those of ordinary skill in the technical field to which the present embodiment belongs will be able to make various modifications and variations without departing from the essential characteristics of the present embodiment. Accordingly, the present exemplary embodiments are not intended to limit the technical idea of the present exemplary embodiment, but are illustrative, and the scope of the technical idea of the present exemplary embodiment is not limited by these exemplary embodiments. The scope of protection of this embodiment should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present embodiment.

1000: drying system
100: heat exchanger 105: case
111: exhaust gas inlet 113: exhaust gas outlet
130: thermal medium oil heating unit 140: carrier air heating unit
200: dryer 205: dryer case
230: vehicle 231: mainframe
233: main disk 235: sub disk
241: carrier air inlet 243: carrier air outlet

Claims (7)

delete delete As a sewage sludge dryer of sewage sludge drying system,
A case in which a sewage sludge input port and a sewage sludge discharge port are formed, and a first inner space through which the sewage sludge moves;
It is rotatably disposed in the first internal space, and a second internal space through which the heat medium oil heated in the heat exchanger of the sewage sludge drying system moves is formed inside, and moves the sewage sludge toward the sewage sludge outlet. Way;
A carrier air inlet formed outside the case and into which the carrier air heated by the heat exchanger is introduced; And
It is formed on the outside of the case, and includes a carrier air outlet through which the floating matter generated by drying of the sewage sludge flows out with the carrier air,
The second inner space,
An oil outflow path through which the heat medium oil flows from the heat exchanger is connected,
The sewage sludge,
Sewage sludge dryer, characterized in that dried by the heat medium oil and the carrier air. The method of claim 3,
The second inner space,
A sewage sludge dryer, characterized in that an oil inflow path for moving the heat medium oil used for drying the sewage sludge to the heat exchanger is connected. The method of claim 3,
The moving means,
A main frame rotatably disposed in the first inner space and having the second inner space formed therein; And
And one or more main disks disposed on the outer surface of the main frame along the moving direction of the sewage sludge and having a shape protruding in the direction of the first inner space. The method of claim 5,
It is disposed on the inner surface of the case, further comprising one or more sub-disks having a shape protruding in the direction of the first inner space,
The sub-disc,
A sewage sludge dryer, characterized in that it is disposed at a position corresponding to one or more clearance spaces formed between the main disks, has a predetermined separation distance from the main disks, and is fitted with the main disks. delete

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